Damage Induced by a Spherical Indentation Test in Tool Steels Detected by Using Acoustic Emission Technique
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- 作者:E. Martinez-Gonzalez (1)
G. Ramirez (2)
J. Romeu (1)
D. Casellas (2)
1. Laboratori d鈥橢nginyeria Ac煤stica i Mec脿nica (LEAM) ; Departament d鈥橢nginyeria Mec脿nica (DEM) ; Universitat Polit猫cnica de Catalunya (UPC) ; EUETIB ; Urgell 187 ; 08036 ; Barcelona ; Spain
2. Fundaci贸 CTM Centre Tecnol貌gic ; Av. Bases de Manresa 1 ; 08242 ; Manresa ; Spain - 关键词:Acoustic emission ; Damage mechanisms ; Spherical indentation ; Microstructure ; Micro ; mechanics ; Signal
- 刊名:Experimental Mechanics
- 出版年:2015
- 出版时间:February 2015
- 年:2015
- 卷:55
- 期:2
- 页码:449-458
- 全文大小:2,058 KB
- 参考文献:1. Advanced High Strength Steel (AHSS). Application Guidelines. Version 4.1. (June 2009) International Iron & Steel Institute. Committee on Automotive Applications. http://www.worldautosteel.org. Accessed 1 June 2013
2. Picas I, Hernandez R, Casellas D, Valls I (2010) Strategies to increase the tool performance in punching operations of UHSS. R. Kollek (Ed.), Proc. IDDRG, Graz, Austria, 325鈥?34.
3. Mishnaevsky, L, Lippmann, N, Schmander, S (2003) Micromechanisms and modeling of crack initiation and growth in tool steels: role of primary carbides. Matter Res Adv Technol 94: pp. 676-681
4. Fukaura, K, Yokoyama, Y, Yokoi, D, Tsujii, N, Ono, K (2004) Fatigue of cold-work tool steels: effect of heat treatment and carbide morphology on fatigue crack formation, life and fracture surface observations. Metall Mater Trans A 35: pp. 1289-1300 CrossRef
5. Berns, H, Broeckmann, C (1997) Fracture of hot formed ledeburitic tool steels. Eng Fract Mech 58: pp. 311-325 CrossRef
6. Picas, I, Cuadrado, N, Casellas, D, Goez, A, Llanes, L (2010) Microstructural effects on the fatigue crack nucleation in cold work tool steels. Proced Eng 2: pp. 1777-1785 CrossRef
7. Martinez-Gonzalez, E, Picas, I, Casellas, D, Romeu, J (2013) Detection of crack nucleation and growth in tool steels using fracture tests and acoustic emission. Meccanica.
8. Johnson, L (1985) Contact mechanics. Cambridge University Press, Cambridge CrossRef
9. Lawn, BR (1998) Indentation of ceramics with spheres: a century after Hertz. J Am Ceram Soc 81: pp. 1977-1994 CrossRef
10. Lawn, BR, Wilshaw, TR (1975) Indentation fracture: principles and applications. J Mater Sci 10: pp. 1049-1081 CrossRef
11. Ramirez, G, Tarres, E, Casas, B, Valls, I, Martinez, R, Llanes, L (2009) Contact fatigue behavior of PVD-coated steel. Plasma Process Polym 6: pp. S588-S591 CrossRef
12. Ramirez, G, Mestra, A, Casas, B, Valls, I, Martinez, R, Bueno, R, G贸ez, A, Mateo, A, Llanes, L (2012) Influence of substrate microstructure on the contact fatigue strength of coated cold-work tool steels. Surf Coat Technol 206: pp. 3069-3081 CrossRef
13. Padture, NP, Lawn, BR (1994) Toughness properties of a silicon carbide with an in-situ induced heterogeneous grain structure. J Am Ceram Soc 77: pp. 2518-2522 CrossRef
14. Faisal, NH, Ahmed, R, Reuben, RL (2011) Indentation testing and its acoustic emission response: applications and its emerging trends. Int Mater Rev 56: pp. 98-142 CrossRef
15. Wereszczak AA, Johanss KE (2008) Spherical indentation of SiC, in Advances in Ceramic Armor II: Ceram Eng & Sci Proc 27(7), John Wiley & Sons, Inc., Hoboken, NJ, USA. Doi: 10.1002/9780470291368.ch4
16. Bouras, S, Zerizer, I, Gheldane, F, Bouazza, MT, Bouzabata, B (2008) Study of the resistance to crack propagation in alumina by acoustic emission. Ceram Int 34: pp. 1857-1865 CrossRef
17. Wereszczak, AA, Daloz, WL, Strong, KT, Jadaan, OM (2011) Effect of indenter elastic modulus on hertzian ring crack initiation in silicon carbide. Int J App Ceram Technol 8: pp. 885-894 CrossRef
18. Fischer-Cripps, AC, Lawn, BR (1996) Indentation stress鈥搒train curves for 鈥渜uasi ductile鈥?ceramics. Acta Mater 44: pp. 519-527 CrossRef
19. Pavon, J, Jim茅nez-Pique, E, Anglada, M, Saiz, E, Tomsia, AP (2006) Monotonic and cyclic Hertzian fracture of a glass coating on titanium-based implants. Acta Mater 54: pp. 3593-3603 CrossRef
20. Zhang, H, Fang, ZZ (2008) Characterization of quasi-plastic deformation of WC鈥揅o composite using Hertzian indentation technique. Int J Refract Met Hard Mater 26: pp. 106-114 CrossRef
21. Tarr茅s, E, Ram铆rez, G, Gaillard, Y, Jim茅nez-Piqu茅, E, Llanes, L (2009) Contact fatigue behavior of PVD-coated hardmetals. Int J Refract Met Hard Mater 27: pp. 323-331 CrossRef
22. Lee, SK, Wuttiphan, S, Lawn, BR (1997) Role of microstructure in Hertzian contact damage in silicone nitride: I. Mechanical Characterization. J Am Ceram Soc 80: pp. 2367-2381 CrossRef
23. Swain, MV, Lawn, BR (1969) A Study of dislocation arrays at spherical indentation in LiF as a function of indentation stress and strain. Physica Datatus Solidi 35: pp. 909-923 CrossRef
24. Swain, MV, Hagan, JT (1976) Indentation plasticity and the ensuing fracture of glass鈥? J Phys D Appl Phys 9: pp. 2201-2214 CrossRef
25. Frank, FC, Lawn, BR (1967) On the theory of Hertzian fracture. Proc R Soc Lond A299: pp. 291-306 CrossRef
26. Picas, I (2012) Mechanical behaviour of tools for shearing Ultra High-Strength Steels: influence of the microstructure on fracture and fatigue micro-mechanisms of tool steels and evaluation of micro-mechanical damage in tools. PhS. Dissertation. Universitat Politecnica de Catalunya (UPC). http://hdl.handle.net/10803/112059
27. Huang M, Jiang L, Liaw PK, Brooks CR, Seeley R, Klarstrom DL (1998) Using acoustic emission in fatigue and fracture materials research. J Mater 50(11)
28. Martinez-Gonzalez, E, Picas, I, Romeu, J, Casellas, D (2013) Filtering of acoustic emission signals for the accurate identification of fracture/ mechanisms in bending tests. Mater Trans 54: pp. 1087-1094 CrossRef
29. Stachowiak, GW, Batchelor, AW (2005) Engineering tribology. Elsevier Butterworh-Heinemann, Burlington
30. Gere, JM, Timoshenko, SP (1997) Mechanics of materials. London PWS Publishing Company, Boston
31. Johnson, L (1968) Engineering plasticity. Cambridge University Press, Cambridge
32. Studman, CJ, Field, JE (1977) The indentation of hard metals: the role of residual stresses. J Mater Sci 12: pp. 215-218 CrossRef - 刊物类别:Engineering
- 刊物主题:Mechanical Engineering
Theoretical and Applied Mechanics
Characterization and Evaluation Materials
Structural Mechanics
Engineering Fluid Dynamics
Engineering Design - 出版者:Springer Boston
- ISSN:1741-2765
文摘
The aim of this study is to monitor the subsurface damage mechanisms of commercial cold-work tool steel by observing acoustic emissions generated in a spherical indentation test. Monotonic loads are applied in the elastic and plastic ranges to damage the specimen. Two types of damage prior to the occurrence of cracking are found: carbide breakage and plastic deformation. The phenomena are confirmed by microscopic images and the good agreement between the estimated carbide fracture strength and previous results. The two types of damage gives rise to different acoustic emission signals: a burst-type, high-amplitude signal for the breakage of carbides and a continuous-type, low-amplitude signal for plastic deformation. It is thus possible to detect and differentiate the incipient damage mechanisms on the subsurface in real time in a spherical indentation test.